FR3026019A1 - COMPACT DISPENSER TRAY FOR CONTACT COLUMNS GAS / LIQUID AT SEA - Google Patents

Abstract

The invention relates to a distributor plate (2) comprising at least one perforated partition (6) delimiting compartments (8, 9). According to the invention, the distributor plate (2) comprises at least one distribution compartment (8), in which the gas and the liquid can pass through the plate, and at least one retention compartment (9), in which the liquid can not cross the board. The retention compartment is located on the periphery of the plateau. The invention also relates to a heat exchange column and / or material between a gas and a liquid equipped with such a distributor plate (2), a floating barge comprising such a column, and the use of the column.

Description

The present invention relates to the field of offshore gas / liquid contact columns (or English offshore), and more particularly the offshore units for gas treatment, CO2 capture, dehydration or distillation. The offshore units for gas treatment and / or CO2 capture by amine washing comprise liquid and gaseous absorption and regeneration columns for fluids. The latter operate in gas / liquid flow against the current or cocurrent and are installed on boats, floating barges or offshore platforms, for example FPSO type (English Floating Production, Storage and Offloading which means platform production of storage and unloading), or of FLNG (Floating Liquefied Natural Gas which means Liquefied Natural Gas Platform). Floating columns can also be fitted with distillation columns or dewatering columns. The columns used in these offshore units for gas treatment and / or capture of CO2 and / or distillation and / or dehydration generally operate on the principle of an exchange of material and / or heat between the gas and the fluid which circulate in the columns. FIG. 1 represents a particular case of a gas treatment column 1 equipped with a distributor plate at the top of the column. Conventionally, this gas treatment column 1 comprises several sections filled by a contactor 3, a distributor plate 2 is disposed above each section 3. The gas / liquid contactor contacts the gas G and the liquid L to allow exchanges. The standard distributors 2 used in the absorption / regeneration or distillation columns generally consist of a collector / distributor plate equipped with chimneys 4 (see FIG. 2). The distribution of the liquid is done by the passage of the liquid in the orifices 5 positioned on the bottom of the plate 2 and the distribution of the gas is by the chimneys 4. Each chimney 4 allows the passage of the gas, according to the mode of operation against current or co-current, from the lower part of the column to the upper part of column 1 or from the upper part to the lower part. The chimneys 4 are projecting from one side of the plate 2 and are perpendicular to it. Each chimney 4 is formed of several walls, for example parallelepipedal or cylindrical which delimit an internal volume which is open on either side of the plate 2. To prevent the liquid from passing into the chimneys 4, the exhaust opening or of arrival of the gas above the plate (according to the mode of operation against the current or co-current), is preferably orthogonal to the longitudinal direction of the chimney 4. The objective of the distributor plate is to distribute the liquid L homogeneously on the gas / liquid contactor 3. The trays equipped with chimneys can be of different types, and the chimneys can be positioned according to different configurations. Various variants of dispensing trays are disclosed in particular in the following patent applications and patents: US6338774B, US2004020238A, US6149136A and US5752538A. The gas / liquid contact columns considered are placed on floating structures, for example of boat type, platform or barge, sensitive to the swell.

As a result, the equipment installed on these units, and in particular the gas / liquid distribution trays, undergo wave movements with up to six degrees of freedom ("yaw, pitch, roll, heave, yaw, cavally"). As an indication, the angle associated with the combination of pitching and rolling oscillations may be of the order of +/- 5 ° with a period of 10 to 20 s. The orders of magnitude of the longitudinal, transverse and vertical accelerations then encountered in the column are respectively of the order of 0.33 / 1.28 / 0.33 m / s 2 at 50 m above the bridge. Under these conditions, the operation of conventional distributor trays equipped with chimneys (Figure 2) can be strongly disturbed. Indeed, the operation of these distributors is mainly gravity, a liquid guard of uniform height "h" must be established on the distributor plate. The square of the speed of passage of the liquid through the orifices 5 located at the bottom of the plate 2 is proportional to the height of the liquid guard (UL2 gh). When the plate 2 is inclined under the effect of the swell (Figure 3), the height of the liquid guard is no longer uniform on the distributor plate (h1> h2) which causes an imbalance in the distribution of the liquid inlet the gas / liquid contactor 3. The quality of distribution and thus the efficiency of the column are strongly impacted. This mal-distribution, if not mastered, can significantly degrade the performance of the column. A significant liquid guard would be required to compensate for these effects, which means an increase in bulk and weight that is not suitable for offshore units. In order to avoid this type of problem, distribution elements that are not very sensitive to horizontal defects have been implemented. These distributors generally consist of a manifold and a distributor connected by one or more relatively long vertical pipes for the distributor to remain in charge regardless of the wave conditions encountered. These distributors are generally insensitive to the effects of waves and generate a good distribution quality but are very cumbersome: their height can be several meters in some cases (US2004020238 A). Another solution to these problems is described in patents FR 2771018 A and FR 2771019 A, it consists in using two distributors (primary and secondary). Each distributor is divided into several compartments in which the liquid is distributed. Thanks to these compartments, the liquid is better distributed during the inclination of the column. However, this solution remains cumbersome because it requires two distributors. In addition, the compartments do not communicate together, the distribution of liquid in the compartments is not balanced.

US Patent 5,132,055, meanwhile, discloses a distributor tray in which the chimneys make it possible to compartmentalize the flow zone of the liquid. According to this document, the chimneys are then all parallel. The compartments therefore all have a different surface. In addition, the parallelism of the chimneys does not ensure a good distribution and a good distribution of the liquid on the entire plate. Indeed, when the slope of the plate is parallel to these chimneys, the height of the liquid guard varies significantly between the two ends of the plate. The patent application FR 2989595 A (US 2013/277868 A) discloses a dispenser tray on which are formed perforated partitions defining compartments.

Perforated partitions make it possible to limit the bad distribution of the liquid. The invention relates to a dispensing tray having at least one perforated partition delimiting compartments. According to the invention, the distributor plate comprises at least one distribution compartment, in which the gas and the liquid can pass through the tray, and at least one retention compartment, in which the liquid can not pass through the tray. The retention compartment is located on the periphery of the plateau. The presence of at least one retention compartment at the periphery of the plate allows a good quality of distribution and good dispersion of the liquid, even for large inclinations of the plateau imposed by the marine environment.

The device according to the invention The invention relates to a distributor plate for a column for the exchange of heat and / or material between a gas and a liquid comprising at least one partition defining compartments on the upper face of said plate, said partition comprising perforations to allow the flow of a portion of the liquid between said compartments, wherein said tray has at least one distribution compartment comprising at least one means for the passage of liquid through said tray and at least one means for the passage of the gas through said tray. Said plate comprises at least one retention compartment at the periphery of said plate having no means for the passage of liquid through said plate. According to the invention, said retention compartment has no means for the passage of gas through said tray. Advantageously, each compartment at the periphery of said plate is a retention compartment.

Preferably, said means for the passage of gas are gas distribution elements in the form of a chimney projecting from the upper face of said plate.

According to an alternative embodiment, said partition has a height greater than or substantially equal to the height of said chimneys. According to one characteristic of the invention, the perforations are arranged at the base of said partition. According to one aspect of the invention, said plate comprises several intersecting partitions. Advantageously, said partitions are composed of two series of partitions, the partitions of each series being parallel to each other and secant to the partitions of the other series.

In addition, the perforations of two parallel partitions delimiting the same compartment may not be aligned. Advantageously, the dimensions 1_, 1 and 1_, 2 of said distribution compartment are between 100 and 1000 mm. Preferably, the dimensions 1_, 3 of said retention compartment are between 40 and 200 mm. According to one embodiment of the invention, the means for the passage of the liquid are orifices and / or chimneys projecting from the upper face of said plate. According to an alternative embodiment of the invention, said plate comprises a secondary distribution system projecting from the lower face of said plate for distributing said liquid from said means for the passage of the liquid. The secondary distribution system may include chimneys and / or baffles. In addition, the invention relates to a heat exchange column and / or material between a gas and a liquid, wherein the two fluids are brought into contact by means of a lining. Said column comprises at least one distributor plate according to the invention for distributing said fluids on said packing. The invention also relates to a floating barge, in particular for the recovery of hydrocarbons, which comprises at least one column according to the invention. In addition, the invention relates to the use of a column according to the invention for a gas treatment process, 002 capture, distillation or air transformation.

BRIEF DESCRIPTION OF THE DRAWINGS Other characteristics and advantages of the method according to the invention will appear on reading the following description of nonlimiting examples of embodiments, with reference to the appended figures and described below.

FIG. 1, already described, illustrates the particular case of a gas treatment or CO2 capture column equipped with a distributor tray at the top of the column. Figure 2, already described, illustrates a distributor tray according to the prior art. Figure 3, already described, illustrates an inclined distributor plate according to the prior art. Figure 4 illustrates a partial view of a distributor tray according to the invention.

Figure 5 illustrates an inclined distributor plate according to the invention. FIG. 6 illustrates a view from above of a distribution compartment according to an example embodiment of the invention. Figure 7 illustrates an alternative embodiment of the dispenser tray according to the invention. Figure 8 illustrates a partial view of a distributor tray according to one embodiment of the invention. Figure 9 is a comparative curve between a distributor plate according to the invention and a distributor plate according to the prior art. DETAILED DESCRIPTION OF THE INVENTION FIG. 4 illustrates a dispensing tray according to the invention, it is an isometric view of a plate cut according to a diameter of the plate. The other part of the plate is deduced by symmetry, with a partition at the level of the cutting plane. The invention relates to a distributor plate for heat exchange column and / or material between a gas and a liquid, conventionally comprising at least one means for the passage of gas (such as a chimney) 4 through the plate 2 , and at least one means for the passage of the liquid (such as an orifice) 5 through the plate 2. In addition, the distributor plate comprises at least one partition 6 for compartmentalizing a face of the tray, the partition 6 is perforated 7 to allow the flow of a portion of the liquid between the compartments 8, 9 formed by the partition 6. According to an exemplary embodiment of the invention, the distributor plate comprises a plurality of partitions 6. The distributor plate 2 according to the invention comprises at least one distribution compartment 8 and at least one retention compartment 9. Each distribution compartment 8 allows the distribution of the fluids and comprises at least one means for the passage of the gas 4 and at least one, preferably one more 5. Preferably, each distribution compartment 8 comprises a single chimney 4 for the passage of the gas and a plurality of orifices 5 for the passage of the liquid. FIG. 6 represents an example of a distribution compartment 8 with a view from above. The illustrated dispensing compartment comprises a central gas stack 4 surrounded by a plurality of orifices 5 for the passage of the liquid. Each retention compartment 9 holds the liquid on the upper face (or surface) of the tray and has no means for the passage of liquid through the tray. Preferably, the retention compartment 9 also has no means for the passage of gas through the tray. The partitions 6 of the retention compartments 9 are also perforated. According to the invention, the retention compartments 9 are situated at the periphery of the plate 2, that is to say that the retention compartments 9 are formed by the partitions 6 and the shell of the column 1. According to one embodiment , an additional partition could be placed on the periphery of the ferrule to facilitate the installation of the dispenser and ensure a good seal between the retention compartments. According to one aspect of the invention, all the compartments at the periphery of the plate 2 are retention compartments 9 and the other compartments, that is to say the central compartments (without delimitation by the ferrule of column 1) are distribution compartments 8. The partitions 6 generate compartments 8, 9 of liquid, which serve as a "barrier" when the tray is inclined. Thus, it maintains a relatively homogeneous liquid guard even with a large inclination. A good quality of liquid distribution on the gas / liquid contactor is therefore guaranteed. The guard of liquid is the interface between the gas and the liquid. The height of the liquid guard corresponds to the level of the liquid relative to the upper face of the tray. In addition, the liquid flow zone is the zone on which the liquid circulates; it is the upper side of the plate, on which the partitions 6 are projecting. In addition, thanks to the perforations 7 of the partitions 6, the liquid can flow over the entire face of the distributor plate 2, thus ensuring a good radial dispersion of the liquid. The retention compartments 9 make it possible to attenuate the accumulation and the decrease of the liquid during the oscillations and thus to ensure a good quality of distribution of the liquid. Figure 5 illustrates a distributor tray according to the invention in an inclined position.

The distributor plate 2 comprises on each side (at the periphery) a retention compartment 9, the central compartments being distribution compartments 8. Compared with FIG. 3, the height of the liquid guard varies less, so the UL liquid outlet, and UL2 differ little. Consequently, the distribution is more homogeneous than with the distributor plate according to the prior art.

According to one embodiment of the invention, the means for the passage of the gas are chimneys 4. According to one characteristic of the invention, the chimneys may be cylindrical, cubic, parallelepipedic, or of any similar form. In addition, the step of the chimneys on the tray may be a triangular or square pitch. According to one aspect of the invention, the means for the passage of the liquid are orifices 5 which equip the tray 2. The orifices 5 may have a triangular or square pitch.

Advantageously, the plate 2 has a number of orifices 5 greater than the number of chimneys 4. In addition, the orifices 5 may be of the same size or of different sizes. According to the embodiment of the invention illustrated in Figure 4, the partitions are divided into two series (or sets) of partitions. In each series, the partitions are parallel to each other, spaced regularly by a length L, and secant to the partitions of the other series, which are spaced regularly by a length 1_, 2. Thus, the distribution compartments 8 have substantially a parallelogram shape, and according to the illustrated rectangle example. Advantageously, according to this embodiment, the partitions 6 have a height greater, less or substantially equal to the height of the chimneys 4. This height is sufficient to ensure a good quality of distribution and further the size of the distributor tray according to the The invention remains identical to the size of a "conventional" dispenser tray. Each distribution compartment 8 comprises a single chimney 4. According to this embodiment, it is possible to choose a spacing 1_, 1 and 1_, 2 substantially equal to the distance separating two adjacent chimneys. Advantageously, the retention compartments 9 have a surface smaller than the surface of the distribution compartments 8, in order to guarantee a large distribution surface. The length 1, 3, which corresponds to the length of the intersecting partitions at the edge of the plate, can in particular be less than the length 1_, 1 (see FIG. It is also possible to determine the length 1_, 1 and / or the length 1_, 2, depending on the characteristics of the desired plateau: an unbalance index IQ (expressed as a percentage), and a maximum inclination angle θ imposed by the marine conditions. To quantify the sensitivity to the marine environment of the plateau, the liquid IQ imbalance index is defined as: eh max hm IQ (%) X100 (equation 1) L, mo yen With: -11_, max: the maximum outflow of liquid one of the compartments of the dispenser. qL, min and the minimum liquid flow out of one of the compartments of the dispenser. a -, L means is the average flow rate out of the dispenser. These flow rates are functions of U [1,2: the speed of the liquid leaving the orifices at the ends of the distributor plate as shown in FIGS. 3 (prior art) and 5 (according to the invention). A low liquid imbalance index value indicates a low sensitivity of the distribution to the effects of waves. Conversely, a high value of this IQ index indicates a strong distribution imbalance. The characteristic distances Lc1, Lc2 of the plateau must be optimized so as to minimize the index of imbalance. Depending on the characteristics of the plateau and the operating conditions (maximum angle of inclination 8 imposed by the marine environment), it is possible to define an optimum length of 1, 1 and 1_, 2 with the combination of the following formulations: h. = ho + Lci 2 tan 0 = ho - Lc, 1.2 tan 0 Ah = h - h = 2L tan 0 UL1 oc Cf V2gh. UL2 oc Cf V2ghmin with:: the coefficient of friction at the orifice, ho: height at equilibrium (19 = 0 °) of the liquid guard in a compartment of the dispenser, h'x: the maximum height of liquid guard in a dispenser compartment, the minimum height of the liquid guard in a dispenser compartment, UL1, UL2 speed of the liquid at the orifice, and the sign "means proportional to. It is therefore possible to determine the lengths L1, 1_, 2 as a function of the plateau geometry and the marine conditions to respect a given imbalance index. For example, to have an index of imbalance IQ <10%, it is necessary that Ah 50mm thus the lengths L1, 1_, 2 must verify the following relation: L, c1,2 <50 (MM). 2 tan 0 According to one embodiment of the invention, each partition 6 contains a single perforation 7. Alternatively and as shown in Figure 4, each partition 6 has two perforations 7. These perforations allow the flow of fluid between the compartments 8, 9, which ensures a good radial distribution of the liquid on the entire distributor plate. The perforations 7 may be circular, oblong, rectangular ... However, the surface of the perforations 7 may, preferably, remain small relative to the surface of the partitions so that the partitions 6 continue to play their main role: to limit the amount of fluid flowing on the plate, to ensure a good homogeneity of the height of the liquid on the plate. In addition, according to this embodiment, to prevent a linear flow of the fluid and to ensure a good radial dispersion of the liquid, the perforations 7 of two parallel walls of a distribution compartment 8 are not aligned (or coaxial), c that is to say that a line that passes through the perforation centers of two parallel partitions, is not parallel to one of the partitions of the compartment 8. Advantageously, the perforations 7 are placed in the lower part of the partitions 6, that is to say near the distributor plate, to facilitate the flow of the liquid; perforations 7 always remain below the height of the liquid guard. The number of compartments (and therefore the number of partitions) may be dependent on the diameter of the tray. Preferably, a large-sized tray is more compartmentalized than a smaller-sized tray.

As a variant of the preferred embodiment of the invention, the following characteristics can be modified: the partitions can form compartments comprising respectively several chimneys for the passage of the gas, the compartments have a triangular shape, for this embodiment, it is possible to have three series of partitions, the partitions of the same series being parallel to each other, and secant to the partitions of the other series, the compartments have a hexagonal shape (for example of the honeycomb type), the perforations of two sides opposite to face of a compartment are aligned, each partition has several perforations. In addition, according to an alternative embodiment illustrated in Figure 7, the distributor plate 2 may comprise a secondary distribution system 10 of the liquid. The secondary distribution system 10 projects from the underside of the tray and serves to distribute the liquid from the liquid passage means over the packing. The secondary distribution system 10 improves the liquid distribution quality by orienting the distribution of the liquid on the packing. For example, the secondary distribution system 10 can direct the liquid to the periphery of the lining under the retention compartments 9. In this case, the height of the liquid guard Hhq corresponds to the height of the liquid above the added tray 2 of the height of the secondary distribution system 10. As illustrated, the secondary distribution system 10 may comprise deflectors 12 which direct the distribution of the liquid. Alternatively, the secondary distribution system may comprise a set of sprinklers (set of several pipes arranged in parallel and equipped with orifices), chimneys projecting on the lower part of the distributor plate, and / or a set of perforated pipes arranged in parallel under the distributor tray.

In addition, according to an alternative embodiment illustrated in FIG. 8 ', the liquid passage means comprise, in addition to the orifices 5, liquid chimneys 11 equipped with at least one perforation (or at least one row of perforations). liquid chimneys 11 projecting from the upper face of said plate 2. This solution allows good flexibility of the distributor plate being adapted to different flow rates. Indeed, when the liquid flow rate is low, the liquid storage height in the dispenser compartment 8 on the plate 2 (height of the liquid relative to the plateau level) is low, only the orifices 5 allow the liquid to pass through the tray. When the liquid flow rate is higher, depending on the embodiment, the liquid holding height increases and the radial openings of the liquid stacks 11 allow the liquid to pass through the tray. The height of the chimneys for the passage of liquid 11 is advantageously less than the height of the chimneys for the passage of gas 4. Alternatively to the variant embodiment of FIG. 8, the liquid passage means may comprise only liquid chimneys 11. , which may be of different heights and / or which may comprise perforations at different heights, so as to make the dispenser tray flexible. According to one embodiment, the dimensions of the plate and its components satisfy the following intervals: the pitch P of the chimneys 4 is between 50 and 500 mm, preferably between 100 and 300 mm, the distribution plate 2 has a height between 100 and 2000 mm, preferably between 600 and 1000 mm, the diameter of the plate 2 is between 300 and 10000 mm, if the shape of the elements 4 is cylindrical, the diameter d is between 50 and 500 mm, the height of the chimneys 4 is between 300 and 2000 mm, preferably between 400 and 700 mm, the distance to the minimum edge of the chimneys 4 is between 50 and 400 mm, and preferably between 100 and 200 mm, the height of the partitions 6 is included between 100 and 2000 mm, preferably between 700 and 1000 mm, the gold diameter of the perforations 7 is between 5 and 100 mm, preferably between 30 and 50 mm, the distances 1, 1 and 1, 2 of the distribution compartments 8 are between 100 and 1000 mm , and preferentially check the following relationship: 50 <(mm) with i = 1 or 2, with 9 maximum angle of inclination, and 1 2 tan the distance L3 of the retention compartments 9 is between 40 and 200 mm.

These different embodiments of the dispenser plate according to the invention can be combined with one another, in particular the variant embodiments of FIGS. 7 and 8; for example chimneys 11 can be connected to deflectors 12.

The invention also relates to a column 1 for exchange of material and / or heat between two fluids, in which two fluids are brought into contact by means of a gas / liquid contactor 3, column 1 comprising at least a first input a liquid fluid, at least a second inlet of a gaseous fluid, at least a first outlet of a gaseous fluid and at least a second outlet of a liquid fluid. The column 1 further comprises a distributor plate 2 as described above, to allow the distribution of fluids on the contactor 3. The column 1 is advantageously an amine washing column but it is suitable for all types of solvents. Advantageously, the gas / liquid contactor 3 is a structured packing bed or bulk. In addition, the invention relates to an offshore floating barge, in particular of the FPSO or FLNG type, in particular for the production and treatment of hydrocarbons. The barge comprises an exchange column of material and / or heat between a gas and a liquid as described above. The column can be part of a gas treatment unit and / or CO2 capture to clean gases produced (or smoked). The column according to the invention can be used in processes of gas treatment, 002 capture, distillation or air transformation. Comparative Example In order to illustrate the advantages of the present invention, it is proposed to compare the results obtained by the invention (embodiment of FIG. 4) with those obtained by a distributor plate according to the prior art as described in the application FR 2989595 A (US 2013/277868 A). In this framework, we use a numerical approach of CFD (Computational Fluid Dynamics can be translated by digital fluid mechanics) which consists in studying the movements of a fluid by the numerical resolution of mass conservation equations. and momentum balance (Navier-Stokes equations). The numerical approach used is an interface tracking type (VOF for Volume of Fluid) described in Hirt & Nichols, JCP 39, 201-225 (1981). This method, well known by those skilled in the art, is well suited to simulate the change of interface topology encountered in the distributor subjected to the movement of the swell (detachment, interface recollement, surf formation ...). The evolution of the two-phase flow is described by the mass conservation equation, momentum conservation equations, and the transport equation of the presence rate.

Calculations were made with Fluent 14.5 ® commercial software (ANSYS, USA). For all the evaluation CFD calculations presented below, the angle associated with the simulated roll motion is +/- 5 ° with a period of 15 s. The properties of the fluids are: PL = 1000 kg / m3, pi = 1 cp, pG = 1.2 kg / m3, t / G = 0.018 cp. The liquid guard height on the distributor considered is 400 mm. A distance to the turning point of the offshore platform of 50 m is taken into account in the calculations. This distance corresponds to the distributors located at the head of the column, exposed to the strongest accelerations. Finally, capillary effects are assumed to be negligible. It is recalled that the distribution efficiency of the proposed system is compared with that of a distributor plate according to the prior art in the case where the plate is subjected to the movements of the swell. The sensitivity to the marine environment of the plateau is quantified by the unbalance index defined by equation (1). Example 1: Properties of the tray according to the prior art - Diameter of the distributor plate: 4000 mm - Diameter of gas stacks: 100 mm - Height of gas stacks: 600 mm - Number of stacks: 120 - Length of compartments 1_, 1 xL, 2: 300 x 300 mm - Opening of the partition: approx. 1% - Sprinkling point density: 84 pt / m2 (number of watering points divided by the total distributor area) - Irrigation rate: 100 m 2 / m 2 / h Example 2: properties of the tray according to the invention (FIG. 4): Diameter of the distributor plate: 4000 mm. Diameter of the gas stacks: 100 mm. Height of the gas stacks: 600 mm. chimneys: 120 - Length of distribution compartments 1_, 1 x 1_, 2: 300 x 300 mm - Length of retention compartments L3: 100 mm - Opening of the partition: approximately 1% - Density of watering point: 84 pt / m2 - Irrigation rate: 100 m3 / m2 / h Figure 9 compares the temporal evolution of the unbalance index e IQ obtained with the two distributor trays. For the distributor plate according to the prior art FR 2989595 A (US 2013/277868 A), curve AA, the average unbalance index over a period of oscillation of the plate is 10 `Vo. With the distributor plate according to the invention, curve INV, the performance is better, in fact, the index of average imbalance is 5.8 `Vo. This example shows that the device according to the invention makes it possible to improve the dispensing efficiency of the dispensing tray in a floating medium.

Claims (17)

CLAIMS1) Dispenser tray for exchange column (1) heat and / or material between a gas and a liquid having at least one partition (6) delimiting compartments (8, 9) on the upper face of said plate (2) said septum (6) having perforations to allow flow of a portion of the liquid between said compartments (8, 9), wherein said tray has at least one dispensing compartment (8) comprising at least one means for dispensing passage of the liquid (5, 11) through said plate (2) and at least one means for the passage of gas (4) through said plate (2), characterized in that said plate comprises at least one retention compartment ( 9) at the periphery of said plate (2) having no means for the passage of liquid through said plate. 2) Tray according to claim 1, wherein said retention compartment (9) has no means for the passage of gas through said tray. 3) tray according to one of the preceding claims, wherein each compartment at the periphery of said tray is a retention compartment (9). 4) Tray according to one of the preceding claims, wherein said means for the passage of the gas are gas distribution elements in the form of a chimney (4) projecting from the upper face of said plate. 5) Tray according to claim 4, wherein said partition (6) has a height greater than or substantially equal to the height of said chimneys (4). 6) tray according to one of the preceding claims, wherein the perforations (7) are arranged at the base of said partition (6). 7) Tray according to one of the preceding claims, wherein said plate comprises a plurality of partitions (6) intersecting. 8) Tray according to claim 7, wherein said partitions (6) are composed of two series of partitions, the partitions (6) of each series being parallel to each other and intersecting the partitions (6) of the other series. 9) Tray according to claim 8, wherein the perforations of two parallel partitions (6) delimiting a same compartment (8, 9) are not aligned. 10) Tray according to one of the preceding claims, wherein the dimensions 1_, 1 and 1_, 2 of said distribution compartment (8) are between 100 and 1000 mm. 11) Tray according to one of the preceding claims, wherein the dimensions 1_, 3 said retention compartment (9) are between 40 and 200 mm. 12) plate according to one of the preceding claims, wherein the means for the passage of the liquid are orifices (5) and / or chimneys (11) projecting from the upper face of said plate. 13) Plate according to one of the preceding claims, wherein said plate comprises a secondary distribution system (10) projecting from the underside of said plate to distribute said liquid from said means for the passage of the liquid (5, 11) . 14) Tray according to claim 13, wherein said secondary distribution system (10) comprises chimneys and / or baffles (12). 15) Column for the exchange of heat and / or material between a gas and a liquid, in which the two fluids are brought into contact by means of a lining (3), characterized in that said column (1) comprises at least one less a distributor plate (2) according to one of the preceding claims for distributing said fluids on said lining. 16) floating barge, in particular for the recovery of hydrocarbons, characterized in that it comprises at least one column (1) according to claim 15. 17) Use of a column according to claim 15 for a method of gas treatment, capture of CO2, distillation or transformation of air.